/*
* Copyright 2002-2018 the original author or authors.
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* https://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
package org.springframework.security.crypto.password;
import java.security.GeneralSecurityException;
import java.security.NoSuchAlgorithmException;
import java.util.Base64;
import javax.crypto.SecretKeyFactory;
import javax.crypto.spec.PBEKeySpec;
import org.springframework.security.crypto.codec.Hex;
import org.springframework.security.crypto.codec.Utf8;
import org.springframework.security.crypto.keygen.BytesKeyGenerator;
import org.springframework.security.crypto.keygen.KeyGenerators;
import static org.springframework.security.crypto.util.EncodingUtils.concatenate;
import static org.springframework.security.crypto.util.EncodingUtils.subArray;
A PasswordEncoder
implementation that uses PBKDF2 with a configurable number of iterations and a random 8-byte random salt value.
The width of the output hash can also be configured.
The algorithm is invoked on the concatenated bytes of the salt, secret and password.
Author: Rob Worsnop, Rob Winch Since: 4.1
/**
* A {@code PasswordEncoder} implementation that uses PBKDF2 with a configurable number of
* iterations and a random 8-byte random salt value.
* <p>
* The width of the output hash can also be configured.
* <p>
* The algorithm is invoked on the concatenated bytes of the salt, secret and password.
*
* @author Rob Worsnop
* @author Rob Winch
* @since 4.1
*/
public class Pbkdf2PasswordEncoder implements PasswordEncoder {
private static final int DEFAULT_HASH_WIDTH = 256;
private static final int DEFAULT_ITERATIONS = 185000;
private final BytesKeyGenerator saltGenerator = KeyGenerators.secureRandom();
private final byte[] secret;
private final int hashWidth;
private final int iterations;
private String algorithm = SecretKeyFactoryAlgorithm.PBKDF2WithHmacSHA1.name();
private boolean encodeHashAsBase64;
Constructs a PBKDF2 password encoder with no additional secret value. There will be {@value DEFAULT_ITERATIONS} iterations and a hash width of {@value DEFAULT_HASH_WIDTH}. The default is based upon aiming for .5 seconds to validate the password when this class was added.. Users should tune password verification to their own systems. /**
* Constructs a PBKDF2 password encoder with no additional secret value. There will be
* {@value DEFAULT_ITERATIONS} iterations and a hash width of {@value DEFAULT_HASH_WIDTH}. The default is based upon aiming for .5
* seconds to validate the password when this class was added.. Users should tune
* password verification to their own systems.
*/
public Pbkdf2PasswordEncoder() {
this("");
}
Constructs a standard password encoder with a secret value which is also included in the password hash. There will be {@value DEFAULT_ITERATIONS} iterations and a hash width of {@value DEFAULT_HASH_WIDTH}. Params: - secret – the secret key used in the encoding process (should not be shared)
/**
* Constructs a standard password encoder with a secret value which is also included
* in the password hash. There will be {@value DEFAULT_ITERATIONS} iterations and a hash width of {@value DEFAULT_HASH_WIDTH}.
*
* @param secret the secret key used in the encoding process (should not be shared)
*/
public Pbkdf2PasswordEncoder(CharSequence secret) {
this(secret, DEFAULT_ITERATIONS, DEFAULT_HASH_WIDTH);
}
Constructs a standard password encoder with a secret value as well as iterations
and hash.
Params: - secret – the secret
- iterations – the number of iterations. Users should aim for taking about .5
seconds on their own system.
- hashWidth – the size of the hash
/**
* Constructs a standard password encoder with a secret value as well as iterations
* and hash.
*
* @param secret the secret
* @param iterations the number of iterations. Users should aim for taking about .5
* seconds on their own system.
* @param hashWidth the size of the hash
*/
public Pbkdf2PasswordEncoder(CharSequence secret, int iterations, int hashWidth) {
this.secret = Utf8.encode(secret);
this.iterations = iterations;
this.hashWidth = hashWidth;
}
Sets the algorithm to use. See
SecretKeyFactory Algorithms
Params: - secretKeyFactoryAlgorithm – the algorithm to use (i.e.
SecretKeyFactoryAlgorithm.PBKDF2WithHmacSHA1
, SecretKeyFactoryAlgorithm.PBKDF2WithHmacSHA256
, SecretKeyFactoryAlgorithm.PBKDF2WithHmacSHA512
)
Since: 5.0
/**
* Sets the algorithm to use. See
* <a href="https://docs.oracle.com/javase/8/docs/technotes/guides/security/StandardNames.html#SecretKeyFactory">SecretKeyFactory Algorithms</a>
* @param secretKeyFactoryAlgorithm the algorithm to use (i.e.
* {@code SecretKeyFactoryAlgorithm.PBKDF2WithHmacSHA1},
* {@code SecretKeyFactoryAlgorithm.PBKDF2WithHmacSHA256},
* {@code SecretKeyFactoryAlgorithm.PBKDF2WithHmacSHA512})
* @since 5.0
*/
public void setAlgorithm(SecretKeyFactoryAlgorithm secretKeyFactoryAlgorithm) {
if (secretKeyFactoryAlgorithm == null) {
throw new IllegalArgumentException("secretKeyFactoryAlgorithm cannot be null");
}
String algorithmName = secretKeyFactoryAlgorithm.name();
try {
SecretKeyFactory.getInstance(algorithmName);
}
catch (NoSuchAlgorithmException e) {
throw new IllegalArgumentException("Invalid algorithm '" + algorithmName + "'.", e);
}
this.algorithm = algorithmName;
}
Sets if the resulting hash should be encoded as Base64. The default is false which
means it will be encoded in Hex.
Params: - encodeHashAsBase64 – true if encode as Base64, false if should use Hex
(default)
/**
* Sets if the resulting hash should be encoded as Base64. The default is false which
* means it will be encoded in Hex.
* @param encodeHashAsBase64 true if encode as Base64, false if should use Hex
* (default)
*/
public void setEncodeHashAsBase64(boolean encodeHashAsBase64) {
this.encodeHashAsBase64 = encodeHashAsBase64;
}
@Override
public String encode(CharSequence rawPassword) {
byte[] salt = this.saltGenerator.generateKey();
byte[] encoded = encode(rawPassword, salt);
return encode(encoded);
}
private String encode(byte[] bytes) {
if (this.encodeHashAsBase64) {
return Base64.getEncoder().encodeToString(bytes);
}
return String.valueOf(Hex.encode(bytes));
}
@Override
public boolean matches(CharSequence rawPassword, String encodedPassword) {
byte[] digested = decode(encodedPassword);
byte[] salt = subArray(digested, 0, this.saltGenerator.getKeyLength());
return matches(digested, encode(rawPassword, salt));
}
Constant time comparison to prevent against timing attacks.
/**
* Constant time comparison to prevent against timing attacks.
*/
private static boolean matches(byte[] expected, byte[] actual) {
if (expected.length != actual.length) {
return false;
}
int result = 0;
for (int i = 0; i < expected.length; i++) {
result |= expected[i] ^ actual[i];
}
return result == 0;
}
private byte[] decode(String encodedBytes) {
if (this.encodeHashAsBase64) {
return Base64.getDecoder().decode(encodedBytes);
}
return Hex.decode(encodedBytes);
}
private byte[] encode(CharSequence rawPassword, byte[] salt) {
try {
PBEKeySpec spec = new PBEKeySpec(rawPassword.toString().toCharArray(),
concatenate(salt, this.secret), this.iterations, this.hashWidth);
SecretKeyFactory skf = SecretKeyFactory.getInstance(this.algorithm);
return concatenate(salt, skf.generateSecret(spec).getEncoded());
}
catch (GeneralSecurityException e) {
throw new IllegalStateException("Could not create hash", e);
}
}
The Algorithm used for creating the SecretKeyFactory
Since: 5.0
/**
* The Algorithm used for creating the {@link SecretKeyFactory}
*
* @since 5.0
*/
public enum SecretKeyFactoryAlgorithm {
PBKDF2WithHmacSHA1,
PBKDF2WithHmacSHA256,
PBKDF2WithHmacSHA512
}
}